Linear short histidine and cysteine modified arginine peptides constitute a potential class of DNA delivery agents.

The success of gene therapy relies on the development of safe and efficient multifunctional carriers of nucleic acids that can overcome extra- and intracellular barriers, protect the nucleic acid and mediate its release at the desired site allowing gene expression. Peptides bear unique properties that are indispensable for any carrier, e.g., they can mediate DNA condensation, cellular targeting, membrane translocation, endosomal escape and nuclear localization. In an effort to design a multifunctional peptide, we have modified an arginine homopeptide R16 by replacement of seven arginines with histidines and addition of one cysteine at each end respectively to impart endosomal escape property while maintaining the DNA condensation and release balance. Addition of histidines imparts endosomal escape property to arginine homopeptide, but their arrangement with respect to arginines is more critical in controlling DNA condensation, release and transfection efficiency. Intriguingly, R5H7R4 peptide where charge/arginine is distributed in blocks is preferred for strong condensation while more efficient transfection is seen in the variants R9H7 and H4R9H3, which exhibit weak condensation and strong release. Addition of cysteine to each of these peptides further fine-tuned the condensation-release balance without application of any oxidative procedure unlike other similar systems reported in the literature. This resulted in a large increase in the transfection efficiency in all of the histidine modified peptides irrespective of the arginine and histidine positions. This series of multifunctional peptides shows comparable transfection efficiency to commercially available transfection reagent Lipofectamine 2000 at low charge ratios, with simple preparative procedure and exhibits much less toxicity.